Passporting credentials between a mobile app and a web browser

ABSTRACT

Systems and methods for passporting credentials provide a mechanism by which a native app on a client device can invoke a service provider&#39;s core web site web addresses (URL) while keeping the existing session active and shared between the two experiences (native app and web flow) so that the end user does not need to re-login at each context switch. The mechanism can include a unique way for the web flow context to communicate conditions and pass control back to the native app context of the shared session.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.15/256,204, filed Sep. 2, 2016, which is a continuation of U.S. patentapplication Ser. No. 14/530,329, filed Oct. 31, 2014, now U.S. Pat. No.9,438,588, issued on Sep. 6, 2016, which is a continuation of U.S.patent application Ser. No. 13/162,842, filed Jun. 17, 2011, now U.S.Pat. No. 8,881,250, issued on Nov. 4, 2014, which are herebyincorporated by reference in their entirety.

BACKGROUND Technical Field

The present disclosure generally relates to providing securecommunications for users of electronic devices running native apps and,more particularly, for facilitating authenticated communication sessionsfrom a client device using both native applications and web browsersconcurrently from the same device.

Related Art

Consumer mobile devices—such as smart phones, personal digitalassistants, note pads, web-enabled pods, and players—and otherdevices—such as point of sale (POS) terminals and ticket kiosks—mayprovide functionality to the user of the device by executing applicationsoftware, known as “apps”. A “native” app—which may be downloadable ormay come pre-packaged with hardware or an operating system, forexample—is typically a software application specially designed toexecute on a particular device, and there are many well-known apps forvarious particular mobile devices. Functionality may also be providedvia what may be known as a “web app”, which is not a piece ofdownloadable software, but actually a web site that is optimized forviewing, for example, on a particular mobile device, such as an iPhone®.For a software developer, creating a true native app (e.g., applicationprogramming interface (API)-based module) may take anywhere from 5 to 20times more effort to implement and push to production than re-using analready built and available web-based functionality.

Both native apps and web apps may provide relative advantages, however,depending on the functionality desired to be obtained. For example, useof a native app may be better for situations in which the functionalityof the app needs to take advantage of features built into a device, suchas motion detection, voice recording, voice recognition, camera, andglobal positioning system (GPS). A native app may be better if it isdesired for the content or service provided by the app to be availableoffline (e.g., in the absence of an Internet connection). On the otherhand, use of a web app may be better for situations in which a web siteand its content already exists and it is desired to provide the samecontent to many users, optimized for viewing by users of many differenttypes of devices.

SUMMARY

According to one or more embodiments of the present invention, methodsand systems for passporting credentials provide a mechanism by which anative app on a device can invoke a service provider's core web site webaddresses (usually specified using a “uniform resource locator” or URL)while keeping the existing session active and shared between the twoexperiences (native app and web flow) so that the end user does not needto re-login at each context switch. The mechanism can include a uniqueway for the web flow context to communicate conditions and pass controlback to the native app context of the shared session. Broadly, themechanism provides the user authentication session ID to the embeddedbrowser—also referred to as “web view control”—to access a web site'sURL for a specific web command, view, or flow that requires the user'scredentials to be used. The unique session identifier may be passed intothe browser in place of the user's credentials to allow for thecontinuation of the authenticated session. The embedded browser is nowthe primary means of the user's interaction and this keeps the sessioncurrent (e.g., not timed-out), allowing the user to continue using theweb interface. Communication from the browser back to the native app maybe accomplished by the native app monitoring URLs requested by theembedded browser, with requests for certain URLs indicating particularactions to be taken by the native app. Once the web portion of the flowis done the user returns to the native app, and the session keeps goingin the native app context of the existing session. Embodiments may allowfor better user experience as the users will not need to re-authenticatethemselves when continuing the same session on the same device.

In one or more embodiments, a system includes: a client device executinga native app and an embedded web browser, in which the native app has adevice session token that provides a session authentication with aserver for a device session between the native app and the server, inwhich the session authentication is based on credentials forauthenticating a user; and the native app invokes the embedded webbrowser, providing the embedded web browser with the device sessiontoken based on the credentials, in which the device session tokenprovides authentication for the session on the embedded web browser.

In another embodiment, a computer-implemented method includes:authenticating a device session from a native app executing on a clientdevice; producing a device session token from the authentication;passing the device session token to authenticate a user when entering aweb flow; and entering the web flow on an embedded browser driven by thenative app, in which a web flow session continues the device sessionbased on the authentication provided from the device session token.

In a further embodiment, a computer program product comprises anon-transitory computer readable medium having computer readable andexecutable code for instructing a processor to perform a method thatincludes: authenticating a device session from a native app executing ona client device; producing a device session token from theauthentication; passing the device session token to authenticate a userwhen entering a web flow; and entering the web flow on an embeddedbrowser invoked by the native app, in which a web flow session continuesthe device session based on the authentication provided from the devicesession token.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is a system diagram illustrating communication between a clientdevice and financial services provider (FSP) in accordance with one ormore embodiments;

FIG. 1B is a flowchart illustrating a process performed by the system ofFIG. 1A in accordance with one or more embodiments; and

FIG. 2 is a flow diagram illustrating a process for entering a web flowbetween a native app and a web app in accordance with an embodiment.

DETAILED DESCRIPTION

In accordance with embodiments of the present invention, passportingcredentials is a mechanism by which a native app can invoke core website uniform resource locators (or URLs) of an entity while keeping anexisting user session active and keeping the session shared between thetwo user experiences (native app and web site) so that the user doesn'tneed to re-login at each context switch between native app and web site.

In some situations, it may be desirable to try to combine the advantagesof both native apps and web apps by accessing a web site from within anative app. When authentication is needed, e.g., the user signs in to anaccount with a user identification (ID) and then provides a password toaccess the account, security may require that a separate, newauthenticated session be started for the web app when the user entersthe web app from the native app. A best practice for maintainingsecurity is that the newly authenticated session in the web app mayentail termination of the authenticated session in the native app toavoid running parallel authenticated sessions. Thus, when the userfinishes with the web app portion of the functionality, the user may berequired to log back in from within the native app to continue with thenative app portion of the functionality. Such a user experience may bedisruptive for the user and may effectively prevent or make impracticalthe use of many desirable and possible types of functionalities.

The entity providing a web site may be, for example, a financial serviceprovider (FSP)—such as PayPal, Inc. of San Jose, Calif.—in which aconsumer or vendor using the service may have an account with the FSP(referred to as an “FSP account”). The user may log in to the user'saccount by providing user credentials, such as a user name and password,that can be used to generate a user authentication session ID. The userauthentication session ID may be provided to the embedded web browser(also referred to as “web view control”) to access the entity's web siteURL for a specific web command, view, or flow that requires the user'scredentials to be used. The unique session identifier is passed into thebrowser in place of the user's credentials to allow for the continuationof the authenticated session between the native app and the browser. Thebrowser may become the primary means of the user's interaction and thepassported session identifier keeps the session current (not timed-out)allowing the user to continue utilizing the web interface. Once the webportion of the flow is done the user may return to native app and thesession may keep going in the existing session context that exists inthe native app.

Passporting credentials in accordance with one or more embodiments mayallow for better user experience as users would not need tore-authenticate themselves when continuing the same session (from nativeapp to embedded browser or vice versa) on the same device. For example,an authenticated session may be initiated when the user starts a nativeapp and provides authentication credentials to an applicationprogramming interface (API) for authentication, and the authenticationAPI returns a session token back to the native app. That session tokenis conventionally used as a mechanism by which the native appauthenticates itself in all the subsequent API calls. That session tokenconventionally is refreshed with each and every API call made. If theuser then launches a web site, the user would need to provide the sameset of credentials, and a new session would be started for the webbrowser, which is separate from the session started on the app.(Conventionally, security concerns may then dictate terminating thenative app session.) One embodiment may instead continue the previouslystarted session and port its credentials into the web browser, allowingthe user to seamlessly continue with the user interface (UI) flowwithout the need for the user to re-authenticate. Ideally, an averageuser would not notice a difference in experience when jumping from anative app UI into a web flow and back into the native app's UI.

By providing seamless transitioning to already built and availableweb-based functionality, one or more embodiments may allow an entitysuch as an FSP to provide their apps with a richer feature set for usersmuch earlier than by the more usual means of creating a true native appAPI-based module, which may take anywhere from 5 to 20 times more effortto implement and push to production than re-using an already built andavailable web-based functionality. For example, the way native mobileapps are developed at one FSP may be heavily geared towards replicatingfunctionality that exists on the FSP's main web site and “porting” it tothe new app. As simple as it may seem on the surface, the processusually requires new APIs to be created to allow mobile app access tocore FSP data and services. This approach generally provides no newfunctionality (albeit there's a new UI and a native app experience) andunnecessarily pollutes the API namespace with too many utility functionswhile accelerating the addition of those new APIs, thus furthercompounding the problem of the API set growing too fast anduncontrollably. The approach enabled by one or more embodiments mayre-use the existing rich web functionality and allow seamlesstransitioning between native app's UI and the web site. A criticalfactor in this experience is that the user does not need to re-loginwhen switching between the native app and the web site, which providesthe desired non-disruptive user experience.

FIG. 1A illustrates a system 100 in which a user may communicate with anentity—such as an FSP—that maintains an infrastructure 102 for providingservices and information. The user may communicate with the entitythrough its infrastructure 102 via a client device 104, which may be,for example, a consumer electronic mobile device such as a smart phone,notepad, point-of-sale (POS) terminal, kiosk, or any other of manyfamiliar devices providing communications and access, for example, tothe Internet or to an intranet or private communications network. Forexample, in the case of POS or kiosks the devices may provide anon-internet (intranet) connection to services. Although that may not bevery common it may be needed as a security measure in closed systems.Many companies provide intranet-only services (such as payroll, humanresources access, legal services, and proprietary documentation).

Client device 104 may include an application 114 (also referred to as“app”) and a web browser 116 (which may be embedded in app 114) thatexecute on client device 104. Client device 104 may provide an abilityto support HTTP protocol in a code which may be, for example, eitherrunning inside the application's memory space or in an external modulethat is directly controlled (driven) by the application, for example, incases where the operating system (OS) or device or mobile deviceplatform may support a type of cross-application control where thedriven app is running outside the driver app's memory space. Forexample, app 114 may drive the execution of embedded browser 116 viaexecution flow 115 in which a “Mobile flow URL” and a “token” are twopieces of data sent into embedded web browser 116 so that embeddedbrowser 116 knows: a) which URL to request; and b) what authenticationdata to provide. Execution flow 115 may be transparent (e.g., notnoticeable) to the user and may include the passing of various forms ofinformation back and forth between app 114 and embedded web browser 116,such as URLs and tokens, as shown in FIG. 1A.

The entity's (or FSP's, for example) infrastructure 102 may include aserver 106, a common gateway interface (CGI) 108 serving web traffic,and a database 110. Server 106 may enable communication 107 betweeninfrastructure 102 and application 114 (also referred to as “app”)executing on client device 104. The expression “native app” generallymay be used to describe that application 114 may be in some sense“optimized” to run on client device 104.

CGI 108 may be a process executing on a computer in the infrastructure102 belonging to an entity such as an FSP. The CGI 108 may comprisebinary code that is proprietary to the entity and may handle web pageprocessing for the entity. CGI 108 may enable communication 109 betweeninfrastructure 102 and embedded web browser 116 executing on clientdevice 104. For example, when a user of client device 104 fills out aform on a web page and sends it in, it usually needs to be processed byan application program (residing in infrastructure 102, for example). Aweb server (which may be included in infrastructure 102) may pass theform information to the application program that processes the data andwhich may send back a response message. This method or convention forpassing data back and forth between the web server and the(infrastructure) application may be provided by the CGI 108.

Both server 106 and CGI 108 may have access to and be in communicationwith database 110, as shown in FIG. 1A, and may provide information onand access to, for example, FSP accounts for users and vendors. Database110 may be a conventional large-volume relational database system(RDBMS), for example, or a low latency, in-memory data storage system.Database 110 may provide a fast-response, low latency, in-memorydatabase access for storing short-lived, non-persistent data, e.g., datathat may be needed for only a few minutes to a few hours. Database 110,for example, may be characterized as a relational database in which adatabase row may provide access to a relatively large amount ofassociated information unlocked by a relatively small amount ofinformation specifying a key to the row. A “token”, e.g., a small dataobject, may be used, for example, to pass information from which such akey ultimately may be determined between various processes, such asserver 106, CGI 108, application 114, and embedded browser 116. Forexample, FIG. 1 shows a token being passed between application 114 andembedded browser 116 in execution flow 115. From a security point ofview, however, none of the components of device 104, e.g., app 114 orembedded browser 116, may be able to determine the key from the tokenpassed in execution flow 115; only components of infrastructure 102,e.g., server 106, CGI 108, may have enough “knowledge” (e.g., cryptokeys, algorithms) to be able to determine secure information from thetoken's internal structure.

FIG. 1B illustrates a process 150 that may occur, according to oneembodiment, in system 100 shown in FIG. 1A. At step 151, a user may openup the native app 114 and provide login credentials via an API of server106. A device session token may be returned back to app 114, and thedevice session token may be used for each and every subsequent API callmade to authenticate this user (with perhaps minor exceptions of APIsthat don't require authentication). The device session token that ispassed back may include, for example, a pointer to a record in database110 that contains all the relevant information that pertains to thissession (referred to as the stored session data). The device sessiontoken may be packed and encrypted, and then encoded, for example.

At step 152, the device session token may be passed into embeddedbrowser 116 as one of the hypertext transfer protocol or securehypertext transfer protocol (HTTP or HTTPS) GET parameters at executionflow 115 and, subsequently, may be passed to the infrastructure 102 intoCGI 108 for processing.

At step 153, the CGI 108 may decode, decrypt, and unpack the passed-insession token and retrieve from database 110 the stored session datathat includes, among other things, an authorization object referred toas a “UserAuthToken”. Different user auth token objects may havedifferent timestamps, permissions, and life cycles independently fromeach other and from the original device session token. Different userauth token objects may be related to one another in that multiple tokenscan point to the same user or device session. In this regard, a devicetoken and a web token may be two separate objects that may differ quitesubstantially yet share the same underlying user or device session. Forexample, one token may become invalid (expired) while the other tokenand the user session both remain valid.

At step 154, the UserAuthToken authorization object may be used toauthenticate the web session on browser 116, effectively achieving aseamless continuation (e.g., requiring no user re-login at this point)of the already active session running from app 114. For example, theuser auth token may be re-packaged (by CGI 108, for example) as a webtoken sharing the same underlying device session, as described above. Inother words, the initial auth token (e.g., the passed-in session token)may be passed into the web flow where it can either be used directly asthe web flow's auth token or the initial auth token may be re-packagedinto a new auth token that is related to the initial auth token and canbe used as the web flow's auth token so long as both tokens share thesame underlying user or device session. The second token (e.g., the webtoken or web auth token) is not required to share the samecharacteristics as the first token (e.g., the device session token oruser auth token) and may have different and independent access rights,lifespan, or other properties.

At step 155, while the web flow (e.g., the continued session from app114 to embedded browser 116) is in active use (e.g., every new pagerequest is done within the token expiration timeframe) the underlyinguser session (e.g., the session on app 114 or device session) remainsactive. For example, the native app 114 may keep refreshing its sessiontoken (the device session token, see step 151) by monitoring URLrequests from the embedded web browser 116. Thus, if a user is currentlylogged in with the native app, the web flow session on the embeddedbrowser continues the device session without requiring the user tore-login so that the user encounters a single shared session running atleast two parallel secure communication interactions (e.g.,communications 107, 109) with the infrastructure 102.

At step 156, once the flow of execution and user interaction returnsback into native app 114, the recently refreshed (in app 114) devicesession token may continue to be valid (e.g., the token has not timedout in the web flow itself) and may be usable to make API calls into theserver 106. For example, to ensure the app's device session token (ofapp 114) is current a call to an appropriate process (e.g., a processtracking the account balance of the user associated with the devicesession token) running on server 106 may be made every time the embeddedbrowser 116 requests a new URL. Alternatively, a generic “keep-alive”technique may be used in which a call may be made to a low-cost or aspecialized keep-alive API to keep refreshing the token.

FIG. 2 illustrates a process 200 for entering a web flow between anative app and a web browser—such as native app 114 and web browser 116executing on client device 104—according to one embodiment. FIG. 2illustrates, for example, how credentials may be passported from anative app authorization token into a web app session authorizationtoken.

In general, when a user opens a web app, or an interactive web page froma browser, and performs some operations—such as transferring moneybetween accounts with an FSP—the operations may be built in the form ofa web flow. In other words, when the user moves from one operation toanother, there is a flow of events and user interaction. The user maysometimes enter sub-flows; for example, when sending money from an FSPaccount, the user may find there is not enough in one account and maydecide to add access to another bank account to fund the transaction(sending money). So then the user may enter a sub-flow for adding accessto the bank account and then return to the web flow for sending moneyand continue with that same web flow. In computer parlance, the flowsmay be kept track of on a stack (e.g., a “navigation” stack), and whenthe user is finished with the adding-bank account sub-flow, thatsub-flow is “popped” off the stack so that the user returns to theprevious web flow.

Any entity—such as an FSP—providing a system 100 having aninfrastructure 102 may provide a framework for its web flows in whicheach web page may include multiple pieces, e.g., states of a processthat can be described using a state-transition diagram. A web flowframework may be executed, for example, by CGI 108. For example, theremay be a state (or step of a process) for a user to enter a “send money”flow, a state that shows whether a user has someone in a contacts list,a state that shows this contacts list to select someone to send moneyto, and so forth. Likewise, there may also be subsets of states thatcorrespond to various sub-flows. There may be many states or steps foreach web page; some steps may be for displaying or changing the displayon the web page, for example, and some steps may function, for example,to make a decision what to do next. Such a decision state may beprovided by flow entry point step 204 of process 200 shown in FIG. 2.

At step 202, a native app (e.g., app 114) may invoke an embedded browser(e.g., embedded browser 116 running on client device 104 either insidethe app's memory space or directly driven by the app) and provide a URLalong with one parameter (e.g., the encrypted device session token) tothe web flow entry point 204 (e.g., entry point for a web page orservice provided by the entity, e.g., an FSP, of infrastructure 102).For example, the device session token may provide a CGI parameter thatincludes information for CGI 108 to find the correct flow entry pointstep 204 for a desired web flow to be continued from a point in theexecution of app 114.

At step 204, labeled “flow entry point”, a CGI (e.g., CGI 108) maydecide whether the passed-in device session token is valid and whetherthe user's session appears to be still active or whether the session hasexpired. For example, the CGI may decode, decrypt, and unpack thepassed-in device session token and retrieve from database 110 the storedsession data that includes an authorization object, e.g., a userauthorization token. Based on all the information, the web flow mayrecognize that the user is logged in and continue on branch 206. If not,the flow may continue on branch 208, as shown.

At branch 206, if the user is logged in (e.g., the native app session isstill valid and not expired) the CGI (e.g., CGI 108) may re-package theauthorization object (e.g., the user authorization token) to be used asan authorization session token for the web flow. For example, the CGImay extract credentials and other information from the authorizationobject and add other information—such as key information for accessingdatabase 110 to find information associated with the current session—tore-package the authorization object as a web auth token. The re-packagedauthorization object, for example, may be passed to web browser 116 viacommunication 109 shown in FIG. 1A. Continuing with branch 206, at step210, the CGI may continue the execution of the flow (for example, onbrowser 116) as if the user is authenticated.

Branch 208—user not logged in—may be taken, for example, if there is afatal error, such as the device session token passed at step 202 was forany reason not good enough—e.g., garbled, bogus, empty, or the sessionhad expired—to be able to proceed. At branch 208, if the user is notlogged in, then the web flow may begin to dispatch the user into a weblogin sub-flow, at step 212.

At step 214, the native app (e.g., app 114) that's driving the executionof the embedded browser 116 may intercept the URL (e.g., the URL passedat execution flow 115) and instead navigate the user into an in-app(e.g., in application 114) login dialog, leaving the embedded browserframe. Once logged in (for example, via the native app's 114 dialog) theuser may have an option to re-enter the same web flow. Alternatively,the driver app 114 may be smarter (e.g., include additional logic) andfirst make sure either that the device session token has indeed expired(and then direct the user into a login screen) or that an unrecoverablefatal error has occurred (and then, for example, display an appropriatemessage to the user, e.g., “try again later”).

Once the application 114 has invoked the web browser 116, however,communication in the direction from web browser 116 to application 114may be limited. In other words, there may be no direct way for the webflow to signal back to a native app that an error has occurred becausethe web flow may be completely ignorant of whether or not it has evenbeen invoked by an app. For example, if there is a fatal error inprocessing a user's request in a web flow—for example, the database isdown—the application 114 would not know that the embedded web pagefailed to render because the web flow will render something (one way oranother), and the application 114 will not have capability to check thetext of what was rendered to make sure the text was correct (because,for example, the text may vary every time). So, in one or moreembodiments, communication back to the driver application (e.g., theapplication 114 that invoked embedded browser 116) may be implemented bythe driver application 114 monitoring the URLs being requested by thebrowser 116. For example, an embedded web flow may signal events, suchas an error condition or exit from the web flow, by requestingpre-defined URLs that are being watched by the driver application. Onceone or more of these special, pre-defined URLs is requested, the driverapplication may intercept the pre-defined special URL and actaccordingly.

There are generally two types of errors: system errors that are fatal(non-recoverable) and user errors (recoverable). The web flow shouldhandle the user (recoverable) errors gracefully without help from thedriver application.

In case of an unrecoverable fatal error (e.g., internal error or systemerror) the web flow should redirect the user into the device login URLto signal the driver application 114 that the web flow has encounteredan unrecoverable error and must be closed. The user should be able tonavigate into the web flow anew, as if it is the first time the flow isbeing entered, as described below, at step 216.

The rationale behind choosing a login URL for this fatal error conditionis as follows: in case there's a (separate) bug in the driver app andthe URL interception fails, there is at least a device-specific-skinnedweb page that takes the device's capabilities (e.g., screen resolution)into account that is being presented to the user. For example, on clientdevice 104 a web page optimized for a mobile device may be presented ifclient device 104 is a mobile device). For another example, if clientdevice 104 is a voice terminal for blind people, an “audio page” may bethe device-specific presentation—which might otherwise have been just aregular block of text—of the information presented to the user on clientdevice 104.

Also in case of tampering with the calling parameters or evidence ofcorrupted data being sent to the server, it is a standard securitymeasure to send the user back to the login step if the authenticitycannot be verified.

For exit from the web flow, a URL may be registered for an embedded webflow to use that can be recognized by the driver application as an“exit” signal. Once the web flow requests that URL, the driverapplication may close the embedded web browser, moving the user “back”in the driver application's navigation stack.

Once logged in (via the native app's dialog) the user may, at step 216,have an option to re-enter the same web flow (for example, by passingthe same URL and a valid device session token to browser 116 at step202).

In implementation of the various embodiments, embodiments of theinvention may comprise a personal computing device, such as a personalcomputer, laptop, PDA, cellular phone or other personal computing orcommunication devices. The payment provider system may comprise anetwork computing device, such as a server or a plurality of servers,computers, or processors, combined to define a computer system ornetwork to provide the payment services provided by a payment providersystem.

In this regard, a computer system may include a bus or othercommunication mechanism for communicating information, whichinterconnects subsystems and components, such as processing component(e.g., processor, micro-controller, digital signal processor (DSP),etc.), system memory component (e.g., RAM), static storage component(e.g., ROM), disk drive component (e.g., magnetic or optical), networkinterface component (e.g., modem or Ethernet card), display component(e.g., CRT or LCD), input component (e.g., keyboard or keypad), and/orcursor control component (e.g., mouse or trackball). In one embodiment,disk drive component may comprise a database having one or more diskdrive components.

The computer system may perform specific operations by processor andexecuting one or more sequences of one or more instructions contained ina system memory component. Such instructions may be read into the systemmemory component from another computer readable medium, such as staticstorage component or disk drive component. In other embodiments,hard-wired circuitry may be used in place of or in combination withsoftware instructions to implement the invention.

Logic may be encoded in a computer readable and executable medium, whichmay refer to any medium that participates in providing instructions tothe processor for execution. Such a medium may take many forms,including but not limited to, non-volatile media, volatile media, andtransmission media. In one embodiment, the computer readable medium isnon-transitory. In various implementations, non-volatile media includesoptical or magnetic disks, such as disk drive component, volatile mediaincludes dynamic memory, such as system memory component, andtransmission media includes coaxial cables, copper wire, and fiberoptics, including wires that comprise bus. In one example, transmissionmedia may take the form of acoustic or light waves, such as thosegenerated during radio wave and infrared data communications.

Some common forms of computer readable and executable media include, forexample, floppy disk, flexible disk, hard disk, magnetic tape, any othermagnetic medium, CD-ROM, any other optical medium, punch cards, papertape, any other physical medium with patterns of holes, RAM, ROM,E2PROM, FLASH-EPROM, any other memory chip or cartridge, carrier wave,or any other medium from which a computer is adapted.

In various embodiments, execution of instruction sequences forpracticing the invention may be performed by a computer system. Invarious other embodiments, a plurality of computer systems coupled bycommunication link (e.g., LAN, WLAN, PTSN, or various other wired orwireless networks) may perform instruction sequences to practice theinvention in coordination with one another.

Computer system may transmit and receive messages, data, information andinstructions, including one or more programs (i.e., application code)through communication link and communication interface. Received programcode may be executed by processor as received and/or stored in diskdrive component or some other non-volatile storage component forexecution.

Where applicable, various embodiments provided by the present disclosuremay be implemented using hardware, software, or combinations of hardwareand software. Also, where applicable, the various hardware componentsand/or software components set forth herein may be combined intocomposite components comprising software, hardware, and/or both withoutdeparting from the spirit of the present disclosure. Where applicable,the various hardware components and/or software components set forthherein may be separated into sub-components comprising software,hardware, or both without departing from the scope of the presentdisclosure. In addition, where applicable, it is contemplated thatsoftware components may be implemented as hardware components andvice-versa—for example, a virtual Secure Element (vSE) implementation ora logical hardware implementation.

Software, in accordance with the present disclosure, such as programcode and/or data, may be stored on one or more computer readable andexecutable mediums. It is also contemplated that software identifiedherein may be implemented using one or more general purpose or specificpurpose computers and/or computer systems, networked and/or otherwise.Where applicable, the ordering of various steps described herein may bechanged, combined into composite steps, and/or separated into sub-stepsto provide features described herein.

The foregoing disclosure is not intended to limit the present inventionto the precise forms or particular fields of use disclosed. It iscontemplated that various alternate embodiments and/or modifications tothe present invention, whether explicitly described or implied herein,are possible in light of the disclosure. Having thus described variousexample embodiments of the disclosure, persons of ordinary skill in theart will recognize that changes may be made in form and detail withoutdeparting from the scope of the invention. Thus, the invention islimited only by the claims.

1. A system, comprising: a non-transitory memory; and one or morehardware processors coupled to the non-transitory memory and configuredto read instructions from the non-transitory memory to cause the systemto perform operations comprising: in response to receivingauthentication credentials associated with a user via a user interface(UI) of a native application, transmitting the authenticationcredentials to a server to request fora session token; in response toreceiving the session token from the server, initiating a device sessionbetween the native application and the server based on the sessiontoken; launching an embedded web browser to provide a web UI within thenative application by providing the session token and a web address tothe embedded web browser; transmitting the session token and the webaddress from the embedded web browser to a the server to automaticallyauthenticate the user in a web session between the embedded web browserand the server without requiring the authentication credentials, whereinthe session token authorizes the server to share at least a portion ofsession data associated with the device session with the web session; inresponse to intercepting a first communication between the embedded webbrowser and the server, resuming the device session based on the sessiontoken; and displaying the UI of the native application for the resumeddevice session.
 2. The system of claim 1, wherein the firstcommunication comprises a first uniform resource locator (URL) request.3. The system of claim 1, wherein the session token and the web addressis transmitted from the embedded web browser to a Common GatewayInterface (CGI) of the server.
 4. The system of claim 1, wherein theoperations further comprise in response to intercepting a secondcommunication between the embedded web browser and the server,refreshing the device session token.
 5. The system of claim 4, whereinrefreshing the device session token comprises transmitting anapplication programming interface (API) call from the native applicationto the server.
 6. The system of claim 2, wherein the operations furthercomprise in response to intercepting a second communication between theembedded web browser and the server, refreshing the device sessiontoken, wherein the second communication comprises a second URL request.7. The system of claim 4, wherein refreshing the device session token isbased on a determination that the second communication is interceptedwithin a token expiration time of the session token.
 8. The system ofclaim 1, wherein the embedded web browser receives a web flowauthorization token from the server based on the user beingauthenticated in the web session, wherein the server shares at least theportion of the session data with the embedded web browser based on theweb flow authorization token.
 9. The system of claim 1, wherein theauthentication credentials comprise login information of the user. 10.The system of claim 1, wherein the operations further comprise:receiving a user input via the UI of the native application during thedevice session; transmitting an application programming interface (API)call and the session token from the native application to the server,wherein the API call is authenticated based on the session token; andrefreshing the session token based on transmitting the API call.
 11. Thesystem of claim 1, wherein the operations further comprise closing theembedded web browser in response to intercepting the firstcommunication.
 12. A method, comprising: in response to receivingauthentication credentials associated with a user via a user interface(UI) of a native application, transmitting, by one or more hardwareprocessors, the authentication credentials to a server to request for asession token; in response to receiving the session token from theserver, initiating, by the one or more hardware processors, a devicesession between the native application and the server based on thesession token; launching, by the one or more hardware processors, anembedded web browser to provide a web UI within the native applicationby providing the session token and a web address to the embedded webbrowser; transmitting, by the one or more hardware processors, thesession token and the web address from the embedded web browser to theserver to automatically authenticate the user in a web session betweenthe embedded web browser and the server without requiring theauthentication credentials, wherein the session token authorizes theserver to share at least a portion of session data associated with thedevice session with the web session; in response to intercepting a firstcommunication between the embedded web browser and the server, resuming,by the one or more hardware processors, the device session based on thesession token; and displaying, by the one or more hardware processors,the UI of the native application for the resumed device session.
 13. Themethod of claim 12, wherein the first communication comprises a firstuniform resource locator (URL) request.
 14. The method of claim 12,further comprising in response to intercepting a second communicationbetween the embedded web browser and the server, refreshing the devicesession token.
 15. The method of claim 14, wherein refreshing the devicesession token comprises transmitting an application programminginterface (API) call from the native application to the server.
 16. Themethod of claim 13, further comprising in response to intercepting asecond communication between the embedded web browser and the server,refreshing the device session token, wherein the second communicationcomprises a second URL request.
 17. The method of claim 14, whereinrefreshing the device session token is based on a determination that thesecond communication is intercepted within a token expiration time ofthe session token.
 18. The method of claim 12, further comprising:receiving a user input via the UI of the native application during thedevice session; transmitting an application programming interface (API)call and the session token from the native application to the server,wherein the API call is authenticated based on the session token; andrefreshing the session token based on transmitting the API call.
 19. Anon-transitory machine readable medium having stored thereonmachine-readable instructions executable to cause a machine to performoperations comprising: in response to receiving authenticationcredentials associated with a user via a user interface (UI) of a nativeapplication, transmitting the authentication credentials to a server torequest for a session token; in response to receiving the session tokenfrom the server, initiating a device session between the nativeapplication and the server based on the session token; launching anembedded web browser to provide a web UI within the native applicationby providing the session token and a web address to the embedded webbrowser; transmitting the session token and the web address from theembedded web browser to the server to automatically authenticate theuser in a web session between the embedded web browser and the serverwithout requiring the authentication credentials, wherein the sessiontoken authorizes the server to share at least a portion of session dataassociated with the device session with the web session; in response tointercepting a first communication between the embedded web browser andthe server, resuming the device session based on the session token; anddisplaying the UI of the native application for the resumed devicesession.
 20. The non-transitory machine readable medium of claim 19,wherein the operations further comprise in response to intercepting asecond communication between the embedded web browser and the server,refreshing the device session token.